Cash register



May 5, 1942.

M. DEMEULENAERE CASH REGISTER J Filed April 18, 1955 8 She'ts-Sheet 1 mew] May 5, 1942.

M. DEMEULENAERE CASH REGISTER Filed April 18, 1935 8 Sheets-Sheet 2 Qemeuj May 5, 1942.

M. DEMEULENAERE CASH REGISTER Filed April 18, 1935 May 5, 1942. E A E 2,282,120

CASH REGISTER Filed April 18, 1935 a Sheets-Sheet 4 y 1942 M. DEMEULENAERE 2,282,120

CASH REGISTER Filed April 18, 1935 8 ee y 5, 1942 M. DEMEULENAERE 2,282,120

CASH REGISTER Filed April 1,8, 1935 8 Sheets-Sheet e 108 109 12 30 10 y 1942- M. DEMEULENAERE 2,282,120 7 CASH REGISTER Filed April 18, 1935 8SheetsSheet '7 M. DEMEULENAERE May 5 1942.

CASH REGISTER Filed April 18, 1935 8' Sheets-Sheet 8 flan? )7? 2619761 7603 Y Patented May 5,1942

CASH REGISTER Marcel Demeulenaere, Brussels, Belgium Application April 18, 1935, Serial No. 17,119

In Belgium January 28, 1935 21 Claims.

My invention relates to cash registers, and has for its primary object to provide a cash register which is capable of carrying out all the necessary or desired operations, whilst having an extremely simple and strong mechanism, operhy small number oi parts, the manipulation of which is rapid and convenient.

Another object the invention is to provide cash register a plurality of totalizers, some of said totaliaers (hereinafter called general tctali'eem) partaking in all registering operations, other tctaiizers (hereinafter called partial tcteliaers) partaking only in certain predetermined opera-tr A further ohject is to provide a cash register, in which all the totallsers are actuated by a single operating member adapted to efiect both the selection of the totallser or totalisers to participate in the operation to be registered, and the actuation of the totalisers selected.

A still further object of the invention is to provide a cash register having for each totaliser a carry-over mechanism, the carry-overs becoming'effective only on the intervention of a member independent or the operating member, thus permitting the correction of any error in a registration. v

A still further object of the invention is to provide, in the cash register, a travelling printing mechanism adapted to print checking tickets 80 after each operation and to print, when desired, the amounts accumulated on any of the totalisers.

A still further object is to arrange the printing mechanism in such manner, that it cooperates 35 with the totalisers in order to reset the totaliser discs to zero.

Further objects and features of the invention will appear during the course of the followin description with reference to the accompanying drawings which illustrate by way of example, an embodiment of the invention.

Figure 1 is a front view, partly in longitudinal section of the whole cash register;

Figure 2 is a longitudinal section of the displaceable supporting mea'ns for the totalizer discs and related pawls:

Figures 3 to 7 are cross-sections through the lines III-IILIV-IV VII- -VII, respectively of Figure 2;

Fig. 7a is a perspective view of the right-hand part of Figure 2.

Figure 8 shows in front view members which, in Figure 1, are hidden;

Figure 9 is a view on a larger scale of the left hand part of Figure s;

Figure it is a cross-section on the line X-X oi Figure 8;

Figure ll shows in front view a detail of Figwe 10;

Figure cross-section on the line XII- scale, or the selector shown in Fig. l3.

Figure 1% is a cross-section on line b-b of Fig. 16a.

Figure 160 is a perspective view of one half of the selector, on line c-c of Fig. 1th.

Figure l? is a cross-section on the line XVII- XVII of Figure 18, showing a selector and a carry-over mechanism;

Figures 17a, 17b and Ho are sectional views each on line :n-x of Fig. 184:, illustrating different positions, and Figure 17d is a sectional view on line z-z oi Fig. 18o;

v:Figure 18 is a longitudinal section of a clerks totaliser and of its selector;

Figure we is a sectional view similar to Fig. 18, with parts in another position;

Figure 19 is a cross-section on the line XIX- XIX of Figure 20, showing the detail of a countor of the operations of a clerirs totaliser;

Figure 20 is a plan viewer counter, in the direction of the arrows XXXX of Figure 19;

Figure 21 is a, side view of the printing mechanism, and v Figure 22 is a front View thereof omitting certain parts.

Figure 23 shows in side view on a smaller scale the ticket mechanism, and

Figure 24 is a plan view or" this mechanism.

Figure 25 is a cross-section on broken line XXVXXV oi Figure 1.

Figure 26 is a cross-section on broken line XXVI-XXVI of Figure 1.

Fig. 27 is a diagrammatic view expressly for the purpose of showing the angular disposition of the several sets of type on one of the character wheels.

The cash register shown on the drawings comprises, from left to right on Figure 1, a general totaliser G, a daily totaliser Q, a first clerks totaliser A with operation counter A and a second clerks totaliser B with operation counter 1 13 It permits, for example, to register separately the operations of two salesmen on the clerks totalisers A and B, of counting the number of these operations on the counting mechanisms A B of registering on the daily totaliser Q all the operations carried out by the two salesmen in one day, and of registeringthe whole of the operations of a week or of a month, for example, on the general'totaliser G. Furthermore,

-an indicator I to the right of the register indicates the amount of each operation.

The various totalisers and counters, as also the indicator, are each constituted by a group of annular discs I0, all identical, each provided with ten teeth bearing the numbers to 9. Distance pieces ll separate the groups of discs and prevent them from shifting in the axial direction.

All the discs III are provided with axial bores and fitted freely on a common shaft or spindle I2 which is mounted horizontally between a bracket [3 and the right hand side wall of the frame l4 Under the action of the piston IS in one direc- 1 tion, and of the resetting spring I8 in the other direction, the bar I! can slide axially in the groove it of the spindle I2, executing a step-bystep movement controlled by an escapement which comprises the rack 28 with circular teeth and two pawls 2|, 22 shown in detail on Figures 13 and 14. Each axial displacement of the bar, permitted by the escapement, corresponds to the distance from center to center between two successive discs III adjacent to each other ofthe totaliser. This bar Il, movable axially in the groove I6 of the spindle I2, is also movable angularly with this spindle and it constitutes the operating member of the discs.

The bar I! and yoke 23 are connected in the manner represented in Figs. 1 and 3. Yoke 23, comprises two plates screwed together (Fig. l). A small pin carried by bar I1 (Fig. 3) engages in a circular groove between the two plates of the yoke, so that the bar I! may be rotated with respect to yoke 23, while the bar and yoke are locked together as regards axial movements.

In its axial movement, the bar I! carries with it by the yoke 23' a set of pawls 24 (Figs. 1, 1'7, and 18) engaging yieldingly with the teeth of the totaliser discs l0. .Each pawl is provided with an eye 25, and said pawls are fitted side by side by their eyes on a sleeve 26 axially rigid withthe yoke 23 and adapted to slide on a fixed spindle 21 parallel to the spindle I2. The set of pawls 24 constitutes the means blocking the discs.

The bar I1 and the set or comb of pawls 24 constricted neck 23 (Figure 19) with the central open part of the disc filled by the spindle I2. Due to the pawls 24 engaging with the teeth of the discs I8 and holding these in a correct angular position, the holes 28 of the different discs are always in line, and form around the spindle l2 ten tunnels in each totaliser. V.

In these tunnels there engage and slide on an axial displacement of the bar II, driving projec tions or buttons 38 projecting from the longitudinal free face of the bar I1. These buttons 38 have a spherical head adapted to the diameter of the holes 28 of the discs II), a restricted neck being able to pass in the restricted part of these holes and a cylindrical body fitted in a recess of the 'bar l1. c

There is a button 30 on the bar I! for each totaliserG, Q, A, B, and for the indicator 1. The three buttons 38, 3%, 30 of the general totaliser G of the daily totaliser Q and of the indicator I are fixed in the bar H. The buttons 30*, 30 of the clerks totalisers are adapted to disappear in their recesses 3|, against the action of a spring 32 (Figures 15, 16). This disappearance is necessary to permit the selective control of one or the other of the clerks totalisers A, B.

The selection is-eiiectedby means of a special arrangement of the fixed parts (Figures 15, 16, 16a, 16b and 160), serving as selectors,- which are at the right of the partial totalisers (Figure l) and comprise each a circular chamber 33*, 33 of less depth than said selectors, the bottom of said chambers having a rim of holes 28 28 respectively (Figures 15, 16, 16a 16b and 160) registering with the holes 28 of the totaliser discs. Some of these holes, which are diflerently located in each selector, are replaced by one or more larger notches, in the form of arcs. 34 occupying the place of two successive holes, whilst the selector ll comprises two notches 35,

' 36 each occupying the place of one hole and leavare axially movable together as a unit, the set of pawls of, the unit moving on the outside of the totaliser discs Ill whilst the bar l1 moves inside ten round holes 28 each communicating by a the Other portion or chamber having a diameter equal to the diameter of shaft I 2, with holes 28 arranged around its periphery except where they are replaced by notches 35, 36 (Figs. 16b, The selector IIA (Fig; 15) is of identical construction, except in that it has one notch 34 instead of the two notches 35, 36 of selector I IB.

In its inoperative position, the bar I! is at the end of its travel to the right (Figures 1 and 18), and the buttons 30* and 30 project vertically from said bar into the chambers 33*, 33 respectively, and face the notches 34 and 35, respectively.

To select a clerks totaliser, it is necessary to shift the actuating bar I1 first axially towards the left to cause the buttons 30*, 30 to enter respectively the notches 34, 35 in front of them, and then angularly by a tenth of a turn in clock wise direction if it is desired to select the totaliser A, or of two-tenths of a turn in clockwise direction if it is the totaliser B which is to be selected. It this is necessary to rotate bar I! through a predetermined angle in order to permit either; button 30A or button 303 to project into a notch (respectively 34 or 36), before'the next axial movement of bar I] takes place. Only that button The selector II comprises a single notch which has come out of the recess 3| can. during the axial movement of the bar, engage the holes 38 of the totaliser corresponding thereto and rotate the discs of said totaliser. After a tenth of a turn, in-fact, the button 30* remains projecting in the wide notch 34 and can thus be. engaged, by a later axial movement of the bar ll, in one of the tunnels formed by the holes 33 of the discs ID of the totaliser A, whilst the button 30 has been forced back into its recess 3| by the arcuate wall of the notch 35, and remains hidden during the later axial displacement of the bar l1, the narrowness of the constricted necks 29 preventing it from leaving its recess to engage in the holes 28 of the discs of the second clerk's totaliser B. This latter is therefore eliminated [while the totaliser A is selected. In other words,

1 the bar H is rotated through two tenths of a turn. At the end oithis angular movement the button 30A is pressed back into the recess Si by the curved side of notch 3t, whereas button 393 stands in the middle oi notch 3'3 where it projects freely. Thus during the subsequent axial movement of bar il the button 393 will be engaged in the holes 23 in the discs .of totaliser B and said totaliser B will be selected while button A will remain hidden and totaliser A will not be operated. Thus, the second clerk's totaliser it is selected. It is clear that in this way up. to nine clerk's totalisers could be selected by causing the bar ii to rotate by nine tenths of a revolution, provided that each clerk's totaliser were fitted with a selector ii having suitable notches.

Since the general totalisers G and Q partake in all registering operations, there is'no selector co-operating with said totalisers. The distance pieces ll adjoining the totalisers G and Q and the indicator I (Fig.1) are annular spacing rings fixed on shaft i2 and having each at their inner periphery a longitudinal groove adapted to receive the corresponding buttons 33G or 38Q respectively, whatever be the angular position of the letter or of bar ii.

To efiect the selection, the operatingmember H, in the example shown, is manipulated by the operator by means of a key 31 (Figures 2, '7 and 7a), the T end 31' of which engages in the slot 20 at the extremity of the rack 20. This key has H H The second web 33 then abuts against the surface 43 and can only enter the hole ll after the operator has turned the key by a tenth of a revolution if it is the key ofthe totaliser A, or by two-tenths of a revolution if it is the key of the totaliser Bythus causing the bar I! to rotate with the spindle I! by the angle necessary to select the desired totaliser A or B.

two webs or bits, the first of which 33 is narrow and parallel to the wings of the 'l'. and the 'second 39 is wide and offset with respect to 3d by run, for example, from 1 to 9 tenths of a revolu-' tion for nine different keys, if the register comprises nine clerks totalisers.

There is made in the outer wall of the register, a vertical keyhole ll for the passage of the key (Figures 1 and 7). When the key is inserted, its end 31' only comes into engagement with the slot 20 at the end of the rack 20 when the web or bit 38, placed vertically, enters the hole 4!. On continuing to insert the key, the operator pushes towards the left the rack 20 and the actuating bar l1, thus engaging the buttons 30 30 into the notches 33, 33 of the selectors It will thus be seen that the web 38 enters hole 4i when the end 31' of the key comes into engagement with the slot 20' at the end of rack 1 20. The key then is inserted further and it is has no action upon the totaliser discs since, during this rotation, all the buttons are engaged in the distance pieces H and selectors li H respectively, and not in the holes 28 of any totaliser discs.

The operator can then fully insert the key and thus press the bar 11 to the end of its travel towards the left, which has for effect to engage the driving buttons 39 30, 30 or 33 and 30 respectively in the general totaliser G, the daily totaliser Q, the clerk's totaliser A or B selected, and the indicator 1..

Actually the whole selection operation of the totalisers is reduced, for the operator, to inserting in the hole ti, and pushing and rotating the key of the totaliser which he desires to select. A stop [:2 arresting the web 39 opposite the hole 4! avoids any groping. The general totaliser G and the daily one Q having to register all the operations of the cash register, do not give rise to selection.

Aiterselection of the totalizers and complete displacement of the bar ll to the left, the key 3] is fully withdrawn so that the bar 11 together with the shaft ii and discs HI may rotate.

The axial displacement of the bar ll to the extreme left under the thrust of the key 31 causes a corresponding displacement of the set of pawls 2 3, the pawls of which slide laterally over the teeth of the discs 1 il. It will be noticed (Figure 1) that, in the plane of each driving button (3W. 3M, 33*, 30 and 30 one pawl is missing in the set, and is replaced by a spacing ring 43 a little wider than a disc I. This permits the individual discs III which are at the moment engaged by the driving buttons to rotate withoutresistance,

whilst all the other discs ID are normally blocked by the pawls.

The unit 11-23 is held in the extreme lefthand position, against the tension effect of the spring l8, by the pawl 2! which engages with the last circular tooth adjacent the slot 20' ofthe rack 20. In this position the mechanism is ready registered in the numerical order allocated to those of the discs III in engagement with the buttons 30 at the moment in question. These discs being opposite spaces in the set of pawls teeth on the rack 20 to be engaged by the pawl 2|, and the spring It brings, the bar back to its initial extreme right-hand position (Figure 1), with the driving pins 30A, 303 within the respective circular chambers 33A, 3313. I

Anexample will now be given, showing the manner in which the wheels III are operated to add items.

Let us suppose the amount to be registered by the general totalizers G and Q and the totalizer A is 349.00. Totalizer A having been selected as explained before, the bar I! is moved to the left as faras it can go (Fig. l), its buttons 30 are engaged in the "hundreds discs of all the operative totalizers. The operator then lowers handle 44 pivoted at 45 through three divisions along scale 45a (starting from the vertical position shown in Fig.13), and by doing so he turns, through three tenths of a turn, shaft I?! with bar ll, buttons 30 and the discs engaged by said buttons. Movement of the handle 44 is transmitted to the shaft l2 through a pawl 46 engaging the teeth of a toothed wheel 41 which latter meshes with a toothed wheel 48 keyed on the shaftv l2. When handle 44 is then raised towards or beyond the vertical position, the angular position of the discs |||is not altered, as the pawl 45 (Fig. 13) idles over the teeth of the wheel 41 without rotating either said wheel or the pinion 48. By pushing handle 44 beyond the vertical position, the operator produces an escapement of bar by one step towards the right, as hereinafter described, the result being that the buttons 30 leave the "hundreds discs and come into engagement with the tens" discs. Having spring 56, which operations will be hereinafter described, until the slot is restored to its initial vertical position. Again the desired totalizer is selected, and bar, I! is moved as far as possible to the left by means of the key 31. As there are no hundreds to be recorded, the handle 44 is pushed backwardly to produce an escapement and to bring about the engagement of the tens discs by the buttons 30, the hundreds" discs remaining in set position. Then handle 44 is lowered through two divisions of the scale to rotate the "tens discs through two tenths of a revolution, the handle is moved back and after a further escapement, it is lowered through three divisions to rotate the units discs through three tenths of a revolution. The handle 44 is again swung rearwardly twice so that the discs l0 in the two decimal places remain in set position.

brought the handle 44 back to vertical position,

the operator now lowers it through four divisions along scale 45a, whereby all the tens discs-are rotated through four tenths of a turn. Again the operator moves the handle beyond vertical to produce a further escapement of bar IT by one step, thus bringing the buttons. 30 into engagement with the units discs. Then handle 44 is lowered through nine divisions along scale 45a, thereby rotating the units discs through nine tenths of a turn. Finally, the handle 44 is twice pushed backwardly to cause two escapements whereby the discs l0 in the two decimal places remain in zero position. The desired number 349.00 thus is set up in all the operative total-- izers, that is to say, in all the totalizers except those in which the buttons 3|! were pushed down during the selection.

Supposing the operator now has to add the After 'each registering operation, the operator rotates shaft 18 by means of crank 15 in order 44 of the handle forces the pawl 22 into engagement and disengages the pawl 2|, the operation being effected by the pawl 22 striking a projection 49 of this pawl 2|. The pawl 22 is movable along its axis 50 (Figures 13, 14) over a distance equal to one tooth of the rack. Liberated from the pawl 2|, the rack driven by the unit |'|24 moves with it. by this distance carrying with it axially the pawl 22 until this latter stops against the head 5| of the spindle 50. If the handle 44 is then brought back into the vertical position, a spring 52 replaces the pawl 2| in engagement with the rack, whilst the pawl 22 is disengaged therefrom by a spring 53 and is drawn back by a spring 54 (Figure 14) into position for a fresh escapement. The complete escapement can be produced by bearing directly on a driving member 2| of the pawl 2| thereby disengaging the latter from the rack 20, the pawl 22 being held in inoperative position by spring 53.

After each escapement whereby in each 'totaliser the corresponding button 30 has been brought into engagement with a fresh disc |0 of a lower numerical order to the preceding one, the operator can lower the handle 44 to cause the rotation of the discs in engagement with the desired number of tenths of a turn and then put back the handle to effect a fresh escapement, and so on.

1 The lowering of the handle 44 and the consecutive rotation of the small wheel 48 cause the rotation in the direction of the arrow (Figure 13) of a large toothed wheel 55 urged in the reverse direction by a spiral spring 56. After the lowering of the handle, a pawl 51 retains the wheel 48 against the action of this spring 55. If the pawl 51 is disengaged by depressing its operating member 58 which is integral with 51 and which turns about the axis 51', the spring 56 causes the counter-clockwise rotation of the small wheel 4,8,with the spindle l2, the pawl 46 of the wheel 41 then resting against a fixed stop 59 and being disengaged from the wheel 41 which can thus rotate with the wheel 48 without carrying the handle 44 with it in clockwise direction beyond the position represented in Fig. 13. Clockwise rotation of the wheel 55 will thus rotate the wheel 41 and handle 44 clockwise until the handle is slightly beyond the position shown in Fig. 13 when the pin 59 will act to disengagepawl 46 from wheel 41 and thus liberate 44 from any further clockwise movement. It is advisable, however, to put the handle beyond the position shown in Fig. 13 before disengaging the pawl 51 by depressing 58. This manipulation permits in particular the operator to cancel or correct a wrong manipulation of the handle 44, having had for efiect to impart an incorrect number of tenths of a turn to the discs I at the moment in engagement with the buttons 30.

When cancelling a wrong manipulation, the

' backward rotation of wheel 48 and of shaft I! with bar I! will be stopped at .the moment when the incorrectly actuated disc is reset to zero, owing to the following arrangement: The discs I01 of the printing mechanism are normally engaged the indicator discs [0. When, after an operatioi'r which is to be cancelled, the spring 56 is permitted to rotate the wheel 48 backwards, and with it the bar i1 and those discs l0 includ an indicator disc which are engaged by projections 30, the said indicator disc rotates the corresponding wheel Hi1 of the printing mechanism until its pin I08 (Fig. 21), is met by the finger I09,

which happens when the discs involved are at zero.

As above stated, each lowering of the handle 44 can impart up to nine-tenths of a turn to the spindle l2, and consequently to the discs I 0 in engagement with the buttons 30. The capacity of rotation of the wheel 55 from one side to the other of a stop piece 50 which it strikes against at the ends of its travel through a spur piece 6|, must therefore be equal to the rotation due to the key 31, plus as many times nine-tenths of a rotation of the spindle I! as there are teeth in the rack 20, since the latter determine the, num

ber of positions of the unit |T24 for which the handle 44 can impart a movement, up to ninetenths of a turn, to successive discs I in each totaliser. In other words it will be seen in Fig. 13 that all the rotational movements of spindle l2 are transmitted to the toothed wheel 55, which can rotate through an angle of almost 360, limited by the pin 5| striking on one or the other side of abutment 60. ,Supposing we have to register the highest number which is 999.99 in the constructional example illustrated, then wheel 55 must be able to turn with pinion 48 while said pinion, together with shaft l2, rotates through five times nine tenths of one turn. But previously, when the selecting operation was performed by means of key the shaft it? with its pinion 48 had already effected a partial rotation (i. e. one tenth of a turn if totalizer A was selected, or two tenths of a turn it totalizer E was selected) and this initial rotation had also been transmitted to wheel 55.

It is thus made possible by actuating the single handle it of the manipulator for the operator to cause the successive rotation of each of the discs ill of each totalizer to introduce into the latter the desired number of units of each numerical order for example of the hundreds, tens, units and decimal fractions of units. At the same time as the discs iii of the different totalizers, the discs of the same numerical order of the indicator I are also rotated by the same amount, and they cause the appearance in a mirror 62 of an amount whether the amount shown is really that which he has desired to introduce into a given digital order and, in case of error,- he can correct by I means of the .push member 58 as described above. In other words, the indicator discs being controlled by a' button 30 which is not collapsible, the indicator will register each item entered in any one of the totalizers, starting each time from zero. The operator thus is enabled to check from the indicator the correctness of each figure in the amount recorded, and also to correct any mistake as already pointed out.

Up to the present, the general operation of the totalizers and their control by the manipulating mechanism which permits of the simultaneous rotation by the desired amount of the discs of the same numerical order in the different totalizers, has been explained. In addition to these movements efieeted positively, there are produced in the totalizers automatic movements for the carry-over of the tens of units of the discs of a numerical order to the discs of the higher numerical order. The carry-over of the tens is prepared automatically, in each totalizer, but-it only becomes operative on the manipulation of a control crank common to all the totalizers, which permits of cancelling a carry-over arising from an incorrect item entry in a given order when the erroneous entry is cleared, as long as the crank has not .been actuated.

The mechanism preparing for the carry-over comprises fiat rings 63, arranged on the spindle l2 where they alternate with the totalizer discs Ill, each of said rings being fixed to the disc Ill located immediately to its right. One of these rings 63 is shown dotted on Figure 17 behind the disc 10 to which it is fixed, which disc on Figure 18, is to its right. It comprises a ring of holes corresponding to the holes 28 of the disc, and it has on its periphery a notch 64 followed by a nose piece 85. I

When the disc [0 to which the ring 63 is fixed has rotated by nine-tenths of a revolution from the zero position, in clockwise direction, (Fig. 17) a finger which was pressed downwardly on the edge of the ring by a stop Glfenters the notch 64 and is carried along, on the following tenth of a turn of the disc, by the nose piece 65 which causes it to rock about its axis 68 beyond the plane passing through the centres of this axis and of the spindle I2. In this position of the finger 66, a spring 89 is tensioned and presses the finger against the ring, but this time upwardly. The finger 66 remains in this position as long as the ring 53 continues to rotate with its disc it in clockwise direction. But if the disc and the ring are rotated in the contrary direction, for example in order to cancel a wrongly formed fig ure, as explained above, the finger 66 enters the notch 64' when it comes opposite it. The ring thencarries it along until above the line of the centres of the spindle it and the axis 68, and its spring returns it into the initial position, which nullifies the preparation of the carry-over.

On the finger there is fixed, opposite the next higher order disc iii, a piece 10 carrying a tooth II, a projection 12, and a counter tooth. or projecting portion 76. In the raised position of the finger, the part .10 through its counter tooth l6 bears against the stop 67, but when the.

finger has been rocked by the nose piece to prepare the carry-over of a. unit to the following disc I, the projection 12 comes into the trajectoryof a cross-arm I6 mounted on a spindle 16 adapted to be actuated by the crank or handle I6 of the register. The carry-oversare thus prepared in each totalizer in the course of each operation. I

When, after having effected the operation, the operator rotates the handle 15, the arm 16 is rotated in clockwise direction (Figure 17) by the spindle l6 and'strikes the projection 12, causing the rocking of the part I6, the tooth ll of which engages between two teeth of thedisc ill to which the unit is to be carried over, and causes this disc to be rotated by a tenth of a turn. To avoid the disc rotating further by inertia, the counter tooth 16 of the part blocks the disc immediately after it has rotated through the desired angle. All risk of error in the carry-overs is thus avoided.

The spindle 16 carries an arm 16 for each totalizer disc, and the successive arms are displaced angularly by 90 so as to actuate successively the parts 16 of the successive discs of the same totalizer, in order that the carry-overs may be eifected from one disc to the other without omission. The arms I6 carry out three rotations for two rotations of the crank 15. The transmission is effected by gears arranged on the lefthand side of the casing, that is to say. a small pinion l1 keyed on the spindle I6 of the crank (Figures 9 and 12) a pinion 16 of double the diameter joined to a larger pinion 60 and a small pinion-6| keyed on the spindle 16 of the arms 16.

A little before the end of the movement of the crank vI5 a cam 62 (Figs. 8 to 1'2) driven through shaft 21 by the pinion 60 acts on an arm of an elbow lever 66 which it causes to oscillate about the axis I4. The other arm of the lever 63 carries the stop 6! and the axis 66 of the carryover fingers 66. On rocking with thelever, the

'- spindle 66 draws back and all the fingers 66 leave the rings 66 and can lift up into. their initial position against the stop 61 under the action of their springs 66.

There now will be given an example for explaining the carry-over operations in a totalizer, reference being made to Figs. I'm-17d.

Su posing the amount previously recorded on I totalizer A is 349.00 and the operator wishes to prepared by the engagement of finger 66 in notch 66. This position is shown in Fig. 17b.

However as the operator has to register not one unit but three units, he does not stop disc III in the position of -Fig. 1711 but he rotates it through three tenths of a turn, thus brin ing disc ill to the position shown in Fig. 170, where the figure 2 is recorded (9+3=12). The Figs. 17a, 17b and 170 also'show .the successive positions of parts 16, II and", the latter in Fig. 17c being in the path'of travel of the arms 16.

previously (Fig. 17d) this movement the tooth II has engaged disc 16" and caused it to rotate through one tenth of a turn. so that it records the figure 7 instead of 6, the required' carry over thus having been effected. Immediately thereafter the counter-tooth I6 engages disc I0" and prevents said disc and the piece HI from rotating further. The spring 66 being under tension will return piece 16 to its initial position as soon as the shaft 66 and stop 6] have been If after committing an error, the operator ro-,

tates backwards the ring 66 (with its associated disc lib-see Figs. 17c and '1'lbthe notch 66 allows the finger 66, drawn by ring 66 and spring 66, to resume its initial position shown in Fig. 17. The carry over which had been prepared by the downward movement of finger 66 thus is cancelled together with the erroneous operation which had caused the carry over to be prepared.

As has been stated above, the clerk's totalizers A and B are each flanked by an operationcounter A B (Figure 1) constituted of discs I 6 iden- At each operaof the latter which rotates, lifts, by the action of its teeth on a wide boss 66 covering all the discs of the totalizer, a spring blade 65 (Figures 19 and 20) the end of which, forming a hook, is thus disengaged from a part 66 similar to the part 16 of the carry over mechanism and mounted like said part III on the spindle 66. This piece 66 oscillates. drawn by a spring 61, it tappet 66 comes in the path of one of the arms 13 which carries it along when the handle" is rotated, so that a tooth 66 of the piece 66 causes the counter disc indicated by l6 to advance by a tenth of a revolution. As heretofore noted, Fig. 1 shows, in axial section, the operation counters A on the left-hand side of totalizer A, and B' on the left-hand side of totalizer B. These two counters are identical with each other. Fig. 20 is a top view showing, on a larger scale, one of said totalizers (for example A") It is seen from Figs. 19 and 20 that the sprin blade 64, 66 is lifted as soon as any one of the discs of the corresponding totaliser is rotated. The piece 66 thus being freed, its spring 61 causes said piece to rotate and bring the tappet 66 into the path of one of the arms 16 (which is not illustrated in Fig. 19, but all the arms 16 are shown in Fig. 8). When the handle I6 is rotated with the shaft 16 and the arm-s 16 the carry over of a unit to the first disc of the counter is effected in the same manner as the carry over in the total isers.

The carry over of tens in the counters takes place in the same manner and by means of identical parts as the carryover in the totalizers. These parts have not been shown in Fig. 19 in order not to overburden the drawing, as it will be understood that they are the same as the parts I6, 66 shown in Fig. 17. Of course, the blades 64,

The operator now turns the crank 16. thus turning shaft 16 and its arms 13. One of these arms strikes projection 12 and causes the piece 16 to rotate still further in the same direction as 66 have nothing to do in the carrying of tens in the counters. The carry over of the tens of one disc to the other of the counter is carried out' as for the totalizer, and the return of the driving members and of the carry over members to the position of rest, apart from the discs, is also controlled by the rocking of the spindle 66 at the end of the movement of the handle 15. It will be understood that the counter marks a unit at each operation of the corresponding clerks totalizer.

The handle or crank 15 controls, directly after each operation registered" by the machine, the printing mechanism intended to print the amount of the operation on tickets delivered by the register, and to fulfil other functions such as the resetting to zero of the indicator I after each operation and of the partial and daily totalizers at the end of the day, as also the printing of the amounts totalled by all the totalizers.

The printing mechanism (Figures 21, 22 and 25) comprises an oscillating printing head comprising a series of character discs I00, each provided with ten teeth IM and loosely mounted side by side on a spindle I02 between two uprights I03. The latter are cross connected at the foot by a sleeve I04 fitted on to a tubular spindle I05 surrounding the spindle 18 of the crank 15, and at the top by a spindle I06 carryin a series of toothed wheels I01 of ten teeth each which engage permanently with the teeth IOI of the character discs. Fi 1 shows on spindle I05 the sleeve I04 carrying the printing head. Said head with the sleeve I04 can slide along the whole length of spindle I05 which is coaxial with spindle 18 (Figs. 1, 21, 22, 26). Fig, 25 shows the printing head in front of totalizer A. The wheels I01 are mounted loosely on the spindle I06 and each can be carried around by it by means of a pin I08 forced along by a radial finger I09 of the spindle I06. In the position of rest of the printing head, the wheels I01 engage with the discs I of the indicator 1. Consequently, each value set edge of the discs I00 (the drawing shows them on the side of the disc for greater clearness) is such that the printing head can effect simultaneously two impressions of a single amount on each side of the vertical plane passing through its axis I02. Fig. 27 shows outside of the large circle the characters which print upon rollers I'M and I25. These characters pass the rollers I26 and I25 in clockwise succession when the character discs I00 turn in unison with the wheels I0 of the indicator. The sleeve I04 of the printing head is in engagement through a pin HI with a longitudinal groove N2 of the tubular spindle I05, which extends up to the left-hand extremity of the register where it carries a triangular plate iI3 (Fig. 10) provided with two small rollers H0, H5.

When at the end of an operation the crank is rotated, the pinion 90 rotates a cam M0 (Figure .10) which forces back the roller II I; and thus causes the plate M3 and the whole of the printing head to rock from right to left about the spindle 10, the uprights E03 being integral with the plate through the tubular spindle I and the sleeve I04. The wheels l0? disengage from the 4 discs I0 of the indicator (Figure 21) whilst a large pawliI I1, pivoting on the spindle I02, which had hitherto been kept away from the wheels I01 by the meetingof a boss I I0 of the stop I I9 with a curved nose piece I20 of this pawl,.block-s the wheels I01 in order to prevent the springs IIO from distending.

The printing head strikes, with the interposing of an inked ribbon I2I, two bands of papers I22, I23, passing over two rollers I24, I25 and prints simultaneously the same amount on the two band-s due to the suitable arrangement of its characters. Coming from a spool I26 (Figures 23, 24, and 25) the strip I22 is intended to be cut up into tickets delivered to the outside of the register through a conduit I21, whilst the strip I23 constitutes the duplicate of the tickets and remains in the register for checking. It unwinds from a spool I20 to wind on to a spool I20. The conveyance from one spool to the other is effected by peripheral contact which dispenses with a special transmission between these spools I20, I29 and ensures the regular feed of the strip in spite of the variations of diameter between the spools due to the quantity of strip unwound from one spool winding on to the other. The spools carried by pivoted arms I30, I32 are drawn one towards the other and toward the roller I25 by a spring I33 attached to the axis of the spool I29.

After the printing of the tickets, the cam IIG releases the roller H4 and a spring I34 (Figure 10) acting on the plate II3, raises the printing head to bring the wheels I01 into engagement with the-discs III of the indicator 1. In this movement, an arm I35 keyed on the tubular spindle I05 causes, by means of a pawl I36 (Figures 23 and 26), the advancement by one tooth of a ratchet wheel I31 integral with a toothed wheel I38 which engages with two pinions I39, I40 of different diameters. The small pinion I33 keyed on the axis of the roller I24 causes the strip I22 to advance by the length of a ticket, through the intermediation of this roller I24, whilst the large pinion I40 causes the strip I23, to advance by a distance one-quarter as much, through the intermediation of the roller I25, this strip I23 constituting the duplicate of the ticket. Due to the reduction, it is possible to deliver a ticket of ordinary size whilst having a duplicate of the ticket occupying only small space on the strip I23 which therefore only takes up a little room in the register.

Each printed ticket is cut from the strip I22 by a knife I 42 integral with a bent arm I43 on which the tappet I44 keyed on the spindle 10 of the crank 15, strikes to actuatethe knife at each rotation of the crank. During the first of each two revolutions of shaft 18, the knife I42 receives an idle movement, since, at that time, the amount is being printed on the paper strip which has not yet been fed forward. During the second revolution of shaft 18, the strip I22 is moved forward by the length of one ticket so that at the end of said.revolution the next movement of knife M2 cuts off the printed ticket.

- The return of the printing head into the raised position brings, the wheels 801 into engagement with the discs of the indicator 1. Just before this takes place-the upper extremity of the curved nose piece 620 strikes the stop I66 and this disengages the pawl ill from the wheels E01. Nevertheless, since the discs I0 are prevented from rotating counter-clockwise by their pawls 24 (Figure l), the wheels I01 remain blocked and the springs H0 remain tensioned. The amount set up therefore remains shown at the indicator. At the commencement of the following operation, the operator bearing on the pusher 50 (Figures 1 and 13) to permit the spring 56 to bring the spindle I2 into its initial angular position by counter-clockwise rotation the, totalizer to be set to zero.

cover of the machine.

which is now possible because all buttons 30 are completely disengaged from the discs and theselectors, starts at the same time the movement for resetting the indicator to zero. To this end,

a lower extension of the pusher 50 acting on a 5 part I45 (Figure 1) which connects all the pawls 24 blocking the discs I of the indicator 1, disengages these pawls from the discs I0 which are of] the amounts accumulated at the totalisers and the resetting to zero of the latter. Whilst the portion of the printing mechanism which comprises the rollers I24, I25 and the ticket spools remains at a fixed position under the indicator I, the printing head IOI, I01 constitutes a carriage which can be movedfrom one end to the other of the register by sliding the sleeve I04 along the tubular spindle I05, in order to be brought opposite one or the other of the totalizers. These movements of the printing head may be controlled by the operator by means of a handle I 46 (Figures 21 and 26) which projects through a vertical slot of the outer casing of the register, which slot forms a portion of the grid of slots in. the front .wall (not shown) of the outercasing.

The handle I46 is mounted on a lever I41 piv oted on the tubular spindle I and coupled to the printing head by the tail of the handle I46 engaging in a catch I40 on one of the uprights I03. This lever carries at the-top a rack with ten teeth I49 which engages with a small pinion I50 keyed on the spindle I06.

When the handle I46 is lowered in the vertical slot of the casing, the lever I41 engaging handle. The operator causes the handle to move upward in this slot which has for effect to raise the printing head, the wheels I01 of which come into engagement with the toothed discs I0 of the totalizer (Figures 25 and 26). At the sametime a bar 83 carried'by the uprights I03, Figs. 22 and 25, engages the heels 04 of the pawls 24 appertaining to the discs I0 of the totalizer in question, thus disengaging these pawls from the the catch I40 causes the printing head to swing towards the position shown in Figure 21 until the roller II5 of the triangular platel I3 comes into contact with a cam I5I (Figure 26) which cause said lever I41 to depress a catch I52 and thus to disengage the 'pawl II1 from the wheels I01, and secondly to impart by means of the rack I49 and the pinion I50 a complete revolution to the spindle I06 which rotates, by its fingers I09, the wheels I01 and I00. The latter are thereby reset to zero and their springs IIO are fully wound up. The lowering of the lever is assisted by a spring I50 and is limited by a stop I54.- It is held in the lowered position by inserting the tail of the handle I46 behind a stop I (Figure 22) formed by an extension of the spindle I06.

Still by means of the handle I46, the operator then shifts the whole printing head horizontally along the spindle I05 until it comes opposite This movement 25). This latter pivots with the pawl whichhas of the handle is guided in a horizontal slot of the Opposite the desired totalizer a vertical slot comes in front of the 7 discs (Figures 21 and 25). If the operator disengages the tail of the handle I46 from the stop I55, the springs IIO distend causing the rotation of the wheels I00 and I01 which rotate the discs I0 counter-clockwise. As will be understood, this movement of the wheels I00 and I01is possible because the pawl H1 is held in inoperative position by engagement of the nose piece I20 with the stop II8. Each disc I0 will rotate until a projection 84 of its periphery strikes against a stop strip I56 on the printing, head. The disc I0 is then at zero whilst the amount which it indicated is transferred to the corresponding disc I00 which has rotated by the same angle but starting from zero. This amount or figure transferred will appear at the lower part of the character disc I 00 in the vertical plane passing through the axis I02. Thus, in this case the character discs I 00 rotate away from the zero position in counter-clockwise direction as shown in Fig. 27 inside the circle. Since the same operation takes'place for each disc of the totalizer and of the printing head the amount and if desired the identification letters registered on the totalizer are transferred to the printing head ribbon I 21 in the plane passing through the axis I02..

The operation is repeated for the resetting to zero of each totalizer, and the printing of the amount registered thereby. After the resetting to zero of the totalizer, a spring 85 (Figures 17 and 25) attached to the bar 05 of the unit I124 brings each pawl 24 back into engagement with its disc I 0, to block it.

A .pawl I50 (Figure 1) actuated at the commencement 'of each operation of the register by the unit I 124 acts on a ratchet wheel I59 to cause the feed forward of the inked ribbon I2I, so as to avoid it being usedconstantly at the same place.

The disengagement of the pawl 24 which is produced to permit the rotation of the discs I0 in clockwise direction, under the action of the carry-over mechanism previously described, is only possible when the unit "-24 is at the terminal position of travel towards the right. The sleeve 26 like the pawl 24 is controlled by a spring attached to the bar 06 and which tends to rock the sleeve clockwise. In this position the sleeve 26, on which are fitted the eyes of the pawls, is free to rotate. When a pawl oscillates under the thrust of a disc I0 rotating clockwise,

it carries the sleeve 25 with it by a notch 81 of its eye 25 and .a rib 08 of the sleeve (Figure oscillated, but its movement does not influence the other pawls of the comb, in the notches 81 of which the rib 00 can freely move.

But when the unit "-24 is moved towards the left to select and actuate the totalizers, the sleeve 26 is prevented from rotating by the engagement of a pin l6l on the shaft 21 with a slot Hill on said sleeve 28 (Figure 2-), and it no longer permits the oscillation of the pawls 24 during the manipulation of the totalizers by means of the bar I! and of the driving buttons 30. It follows that all the discs of the totalizers are blocked except those which are in engagement with the buttons 30 and opposite which the comb of pawls is interrupted, 'as explained above.

It is shown by the present description that the cash register according to the invention is capable of carrying out a large number of operations with acomparatively small number of members and devices. Naturally, the invention is not restricted to the particular members and devices which have been described by way of example, and its scope would not be departed from by introducing modifications.

I claim:

1. In a cash register, a plurality of totalizers each including a plurality of annular discs, a-

rotatable and axially movable drive. member arranged within the discs, selector means, and engaging means for the discs of each totalizer, the several means being effective to selectively establish a driving connection between the discs of any of said totalizers and said drive member through the related engaging means.

2. In a cash register, a plurality of totalizers each including a plurality of annular discs, a rotatable and axially movable drive member arranged within the discs, separate members operable to establish a driving connection between said drive member and the discs of the respective totalizers, and means for selectively rendering the separate members inoperative to facilitate selective operation of the totalizers.

3. In a cash register, a plurality of totalizers each including a plurality of annular discs, a rotatable and axially movable drive member arranged within the discs, disc operating members carried by said drive member, each operating member being operatlvely engageable with the discs of one of said totalizers for operating said discs, and means for selectively rendering the operating members inoperative with respect to the related totalizer discs for selectively controlling operation of said totalizers.

4. In a cash register, a plurality of totalizers each including a plurality of annular discs, a rotatable and axially movable drive member arranged within the discs, disc operating members carried by said drive member, each of said operating members initially occupying an inop erative position displaced from the discs of one of said. totalizers and movable with said drive member into operative driving engagement with said discs, and means coasting with said operating members in their displaced positions for se ment of said drive member and coacting with said operating members in their displaced positions for selectively rendering said operating members inoperative with respect to the related totalizer discs. v

6. In a cash register, a rotatable and axially movable drive member, a plurality of totalizers each including a plurality of discs having central bores receiving said drive member and notches in the walls of the bores, projections movably mounted on said drive member, each of said projections being movable with the drive member into operative driving engagement with the notches of the discs of one of said totalizers, and means for selectively moving said projections with relation to said driving member into inoperative position with respect to the-notches of the discs of the related totalizer.

-7. In a cash register. a rotatable and axially movabledrive member, a plurality of totalizers each including a plurality of discs having central bores receiving said drive member and notches in the walls of the bores, projections movably mounted on said drive member, each of said projections being movable with the drive member into operative driving engagement with the notches of the discs of one of said totalizers, and stationary selector cams one for each projection, the several cams being angularly displaced and operable to move said projections with relation to said driving member into inoperative position with respect to the discs of the related totalizer independence upon the. angular position or said drive member.

8. In a cash register, a drive member, a plurality of totalizers each including a plurality of discs having central bores receiving said drive member and notches in the, walls of the bores, headed projections movably mounted on said drive member, said notches having enlarged outer ends to accommodate insertion of the said headed projections axially of said discs, each of said projections being movable with the drive member into operative driving engagement with the notches of the discs of one of said totalizers, and means for selectively moving the headed projections with relation to said drive member into inoperative position with respect to the notches of the discs of the related totalizer.

9. In a cash register, a rotatable and axially movable drive member, a plurality of totalizers each including a plurality of discs having central bores receiving said drive member and notches in the walls of the bores, projections movably mounted on said drive member, each of said projections being movable with the drive member into operative engagement with the notches oi the discs of one of said totalizers,

lectively rendering said operating members in- Y operatve with respect to the related totalizer discs.

5. In a cash register, a plurality of totalizers tive position displaced from the discs of one of said totalizers and movable with said drive memher into operative driving engagement with said discs, and means operative during rotary movemeans for selectively moving said projections with relation to said drive member into inoperative position with respect to the notches or the discs of the related totalizer, groups of pawls moved with the drive member during its axial displacement and positioned to engage and re-- tain the discs of several totalizers with the ex-= ception of the discs engaged by said projections,

10. In a cash register, a plurality of totalizers each including a plurality of discs having notched bores, a rotatable shaft mounted in said bores and having a longitudinal groove, a bar slidable in said groove, projections movably mounted on said bar, each of said projections being movable with said bar into operative driving engagement with the notches of the discs oi one of said totalizers, and means for selecmembers being movable with the drive member into operative engagement with the discs of one of said individual totalizers, and selecting means for each operating member operable in dependence upon the extent of angular movement of the drive member to selectively control engagement of the operating members with the related 'totalizer discs.

12. In a cash register, a rotatable and axially I movable drive member, a plurality of totalizers each including a plurality of discs having central bores receiving said drive member and notches in the walls of the bores, projections movably mounted on said drive member, each of said projections being movable with the drive member into operative engagement with the notches of'thediscs of one of said totalizers, and stationary selectors having cam surfaces at different angular .positions for selectively moving said projections with relation to said drive member into inoperative position with respect to the discs of the related totalizer independence upon the angular position'of said drive member, and key means for turning said drive member through variable angles in dependence upon the position of said cam surfaces. i

13. In a cash register, a rotatable and axially movable drive member, a plurality of totalizers each including a plurality of discs having central bores receiving said drive member and notches in the walls of the bores, projections movably mounted on said drive member, each of said projections being movable with the drive member into operative engagement with, the

- notches of the discs of one of said totalizers,

and stationary selectors having cam surfaces at difie'rent angular positions for selectively moving said projections withrelation to said drive member into inoperative position with respect to the discs of the related t'otalizer in dependence upon the angular position of said driv member, and key means for turning said drive member through variable angles in dependence upon the position of said cam surface and for displacing said drive member longitudinallyto move cerone of said totalizers, means for selectively moving said projections with relation to said bar into inoperative position with respect to the notches ofthe related totalizer, the rotary movement of said shaft and bar in one direction effecting the setting of the discs of the totalizer engaged by the operative projection, means normally tending to rotate the shaftand bar in the opposite direction and operable to restore incorrectly set discs to initial position, and means for controlling the restoring means.

16. In a cash register, a .totalizer including a plurality of discs, a counter, operating means for 4 said totalizer, normally ineflective operating means for the counter, and means operated by any totalizer disc when operated to render the counter operating means effective.

17. In a cash register, a plurality of totalizers each including a plurality of annular discs, an

indicator including a plurality of annular discs having visible indicating numerals thereon, a

1 rotatable and axially movable drive member. ar-

ranged within the discs of the totalizers and indicator, disc operating members vcarried by tain of the projections into operative engagement with the related totalizer discs.

14. In a cash register, a rotatable grooved shaft, a plurality of totalizers each including a plurality of discs having bores receiving said shaft and notches in the walls of the bores, a bar longitudinally slidable in the groove of said shaft, projections yieldably fitted in said bar, each of saidprojections being movable with the 7 bar into operative engagement with the notches of the discs of one of said totalizers, stationary selectors having internal camming notches disposed at diiferent angular positions, said camming notches being operable to 'move at least on of said projections with relation to said. shaft into inoperative position'with respect to the discs of the related totalizer when said shaft said drive member, one of said operating members having a fixed projection on and movable with the drive member into operative driving engagement with the discs of the indicator, each of the other operating members being movable with the drive member into operative engagement with the discs of one of said totalizers, and means for selectively moving the projections related to the totalizers with relation to the drive member into inoperative position with respect to the discs of the related totalizer.

18. In a cash register, a plurality of totalizers each including a set of toothed discs, means for operating said discs, a printing head carriage mounted for sliding and swinging movement, a set of toothed wheels mounted to slide and swing with the carriage into mesh with the discs of any of said totalizers, means for rotating said wheels when swung out of mesh with said discs,

spring return means tensioned during rotation of said wheels by said rotating means, releasable means for locking said wheels with the spring means tensioned, said spring return means being operable upon release of said locking means to rotate the wheels and the discs in mesh therewith, and means to arrest the movement of the wheels and discs in a predetermined position.

locking means and rotating said wheels when swung out of mesh with turn means tensioned wheels by said rotating said discs, spring reduring rotation oi said means, releasable means for locking said wheels with the spring means tensioned, means operable to release the irst mentioned locking means when the wheels are moved into mesh with the discs, said spring return means being operable upon release of second mentioned locking means to rotate the wheels and the discs in mesh therewith, and means to arrest the movement oi. the wheels and discs in a predetermined position.

20. In a cash register, a plurality of totalizers each including a set of toothed discs, means for operating said discs, releasable means for retaining said discs in adjusted position, a printing head carriage mounted for sliding and swinging movement, a set of rotatable spring driven toothed wheels mounted to slide and swing with said carriage into mesh with the discs of any 0! said totalizers, releasable means for locking said wheels against rotation, means operable when said wheels are in mesh with said discs to release said retaining means, said spring driven wheels being operable upon release of the looking means to drive the toothed discs meshing therewith, and means to arrest the movement of the discs and wheels in a predetermined position.

21. In a cash register, a plurality of totalizers each including a plurality of annular discs, a rotatable and axially movable drive member arranged within the discs, 8. disc engaging and operating member for each totalizer carried by and movable with the drive member, and selecting means for each operating member operable in dependence upon the extent of angular movement of the drive member to selectively control engagement of he operating members with the discs. 

